1000 resultados para Andean potato mottle virus
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Pós-graduação em Agronomia (Proteção de Plantas) - FCA
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Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)
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The objective of this work was the biological and molecular characterization of a begomovirus detected in São Joaquim de Bicas, Minas Gerais, Brazil, named TGV-[Bi2], by determining its host range, complete nucleotide sequence and phylogenetic relationships with other begomoviruses. Biological characterization consisted of a host range study using either sap inoculation or particle bombardment as inoculation methods. The yellow spot virus can infect plants in Solanaceae and Amaranthaceae, including economically importat crops as sweet pepper, and weeds as Datura stramonium and Nicotiana silvestris. For the molecular characterization, the full-length genome (DNA-A and DNA-B) was amplified, cloned and completely sequenced. Sequence comparisons and phylogenetic analyses indicated that TGV-[Bi2] constitutes a novel begomovirus species named Tomato yellow spot virus (ToYSV), closely related to Sida mottle virus (SiMoV).
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The culture and commercialization of ornamental plants have considerably increased in the last years. To supply the commercial demand, several Hemerocallis and Impatiens varieties have been bred for appreciated qualities such as flowers with a diversity of shapes and colors. With the aim of characterizing the tobamovirus isolated from Hemerocallis sp. (tobamo-H) and Impatiens hawkeri (tobamo-I) from the USA and São Paulo, respectively, as well as to establish phylogenetic relationships between them and other Tobamovirus species, the viruses were submitted to RNA extraction, RT-PCR amplification, coat-protein gene sequencing and phylogenetic analyses. Comparison of tobamovirus homologous sequences yielded values superior to 98.5% of identity with Tomato mosaic virus (ToMV) isolates at the nucleotide level. In relation to tobamo-H, 100% of identity with ToMV from tomatoes from Australia and Peru was found. Based on maximum likelihood (ML) analysis it was suggested that tobamo-H and tobamo-I share a common ancestor with ToMV, Tobacco mosaic virus, Odontoglossum ringspot virus and Pepper mild mottle virus. The tree topology reconstructed under ML methodology shows a monophyletic group, supported by 100% of bootstrap, consisting of various ToMV isolates from different hosts, including some ornamentals, from different geographical locations. The results indicate that Hemerocallis sp. and I. hawkeri are infected by ToMV. This is the first report of the occurrence of this virus in ornamental species in Brazil.
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Pós-graduação em Agronomia (Proteção de Plantas) - FCA
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Los patógenos han desarrollado estrategias para sobrevivir en su entorno, infectar a sus huéspedes, multiplicarse dentro de estos y posteriormente transmitirse a otros huéspedes. Todos estos componentes hacen parte de la eficacia biológica de los patógenos, y les permiten ser los causantes de enfermedades infecciosas tanto en hombres y animales, como en plantas. El proceso de infección produce efectos negativos en la eficacia biológica del huésped y la gravedad de los efectos, dependerá de la virulencia del patógeno. Por su parte, el huésped ha desarrollado mecanismos de respuesta en contra del patógeno, tales como la resistencia, por la que reduce la multiplicación del patógeno, o la tolerancia, por la que disminuye el efecto negativo de la infección. Estas respuestas del huésped a la infección producen efectos negativos en la eficacia biológica del patógeno, actuando como una presión selectiva sobre su población. Si la presión selectiva sobre el patógeno varía según el huésped, se predice que un mismo patógeno no podrá aumentar su eficacia biológica en distintos huéspedes y estará más adaptado a un huésped y menos a otro, disminuyendo su gama de huéspedes. Esto supone que la adaptación de un patógeno a distintos huéspedes estará a menudo dificultada por compromisos (trade-off) en diferentes componentes de la eficacia biológica del patógeno. Hasta el momento, la evidencia de compromisos de la adaptación del patógeno a distintos huéspedes no es muy abundante, en lo que se respecta a los virus de plantas. En las últimas décadas, se ha descrito un aumento en la incidencia de virus nuevos o previamente descritos que producen enfermedades infecciosas con mayor gravedad y/o diferente patogenicidad, como la infección de huéspedes previamente resistentes. Esto se conoce como la emergencia de enfermedades infecciosas y está causada por patógenos emergentes, que proceden de un huésped reservorio donde se encuentran adaptados. Los huéspedes que actúan como reservorios pueden ser plantas silvestres, que a menudo presentan pocos síntomas o muy leves a pesar de estar infectados con diferentes virus, y asimismo se encuentran en ecosistemas con ninguna o poca intervención humana. El estudio de los factores ecológicos y biológicos que actúan en el proceso de la emergencia de enfermedades infecciosas, ayudará a entender sus causas para crear estrategias de prevención y control. Los virus son los principales patógenos causales de la emergencia de enfermedades infecciosas en humanos, animales y plantas y un buen modelo para entender los procesos de la emergencia. Asimismo, las plantas a diferencia de los animales, son huéspedes fáciles de manipular y los virus que las afectan, más seguros para el trabajo en laboratorio que los virus de humanos y animales, otros modelos también usados en la investigación. Por lo tanto, la interacción virus – planta es un buen modelo experimental para el estudio de la emergencia de enfermedades infecciosas. El estudio de la emergencia de virus en plantas tiene también un interés particular, debido a que los virus pueden ocasionar pérdidas económicas en los cultivos agrícolas y poner en riesgo la durabilidad de la resistencia de plantas mejoradas, lo que supone un riesgo en la seguridad alimentaria con impactos importantes en la sociedad, comparables con las enfermedades infecciosas de humanos y animales domésticos. Para que un virus se convierta en un patógeno emergente debe primero saltar desde su huésped reservorio a un nuevo huésped, segundo adaptarse al nuevo huésped hasta que la infección dentro de la población de éste se vuelva independiente del reservorio y finalmente debe cambiar su epidemiología. En este estudio, se escogió la emergencia del virus del mosaico del pepino dulce (PepMV) en el tomate, como modelo experimental para estudiar la emergencia de un virus en una nueva especie de huésped, así como las infecciones de distintos genotipos del virus del moteado atenuado del pimiento (PMMoV) en pimiento, para estudiar la emergencia de un virus que aumenta su patogenicidad en un huésped previamente resistente. El estudio de ambos patosistemas nos permitió ampliar el conocimiento sobre los factores ecológicos y evolutivos en las dos primeras fases de la emergencia de enfermedades virales en plantas. El PepMV es un patógeno emergente en cultivos de tomate (Solanum lycopersicum) a nivel mundial, que se describió primero en 1980 infectando pepino dulce (Solanum muricatum L.) en Perú, y casi una década después causando una epidemia en cultivos de tomate en Holanda. La introducción a Europa posiblemente fue a través de semillas infectadas de tomate procedentes de Perú, y desde entonces se han descrito nuevos aislados que se agrupan en cuatro cepas (EU, LP, CH2, US1) que infectan a tomate. Sin embargo, el proceso de su emergencia desde pepino dulce hasta tomate es un interrogante de gran interés, porque es uno de los virus emergentes más recientes y de gran importancia económica. Para la emergencia de PepMV en tomate, se recolectaron muestras de tomate silvestre procedentes del sur de Perú, se analizó la presencia y diversidad de aislados de PepMV y se caracterizaron tanto biológicamente (gama de huéspedes), como genéticamente (secuencias genomicas). Se han descrito en diferentes regiones del mundo aislados de PMMoV que han adquirido la capacidad de infectar variedades previamente resistentes de pimiento (Capsicum spp), es decir, un típico caso de emergencia de virus que implica la ampliación de su gama de huéspedes y un aumento de patogenicidad. Esto tiene gran interés, ya que compromete el uso de variedades resistentes obtenidas por mejora genética, que es la forma de control de virus más eficaz que existe. Para estudiar la emergencia de genotipos altamente patogénicos de PMMoV, se analizaron clones biológicos de PMMoV procedentes de aislados de campo cuya patogenicidad era conocida (P1,2) y por mutagénesis se les aumentó la patogenicidad (P1,2,3 y P1,2,3,4), introduciendo las mutaciones descritas como responsables de estos fenotipos. Se analizó si el aumento de la patogenicidad conlleva un compromiso en la eficacia biológica de los genotipos de PMMoV. Para ello se evaluaron diferentes componentes de la eficacia biológica del virus en diferentes huéspedes con distintos alelos de resistencia. Los resultados de esta tesis demuestran: i). El potencial de las plantas silvestres como reservorios de virus emergentes, en este caso tomates silvestres del sur de Perú, así como la existencia en estas plantas de aislados de PepMV de una nueva cepa no descrita que llamamos PES. ii) El aumento de la gama de huéspedes no es una condición estricta para la emergencia de los virus de plantas. iii) La adaptación es el mecanismo más probable en la emergencia de PepMV en tomate cultivado. iv) El aumento de la patogenicidad tiene un efecto pleiotrópico en distintos componentes de la eficacia biológica, así mismo el signo y magnitud de este efecto dependerá del genotipo del virus, del huésped y de la interacción de estos factores. ABSTRACT host Pathogens have evolved strategies to survive in their environment, infecting their hosts, multiplying inside them and being transmitted to other hosts. All of these components form part of the pathogen fitness, and allow them to be the cause of infectious diseases in humans, animals, and plants. The infection process produces negative effects on the host fitness and the effects severity will depend on the pathogen virulence. On the other hand, hosts have developed response mechanisms against pathogens such as resistance, which reduces the growth of pathogens, or tolerance, which decreases the negative effects of infection. T he se responses of s to infection cause negative effects on the pathogen fitness, acting as a selective pressure on its population. If the selective pressures on pathogens va ry according to the host s , probably one pathogen cannot increase its fitness in different hosts and will be more adapted to one host and less to another, decreasing its host range. This means that the adaptation of one pathogen to different hosts , will be often limited by different trade - off components of biological effectiveness of pathogen. Nowadays , trade - off evidence of pathogen adaptation to different hosts is not extensive, in relation with plant viruses. In last decades, an increase in the incidence of new or previously detected viruses has been described, causing infectious diseases with increased severity and/or different pathogenicity, such as the hosts infection previously resistants. This is known as the emergence of infectious diseases and is caused by emerging pathogens that come from a reservoir host where they are adapted. The hosts which act as reservoirs can be wild plants, that often have few symptoms or very mild , despite of being infected with different viruses, and being found in ecosystems with little or any human intervention. The study of ecological and biological factors , acting in the process of the infectious diseases emergence will help to understand its causes to create strategies for its prevention and control. Viruses are the main causative pathogens of the infectious diseases emergence in humans, animals and plants, and a good model to understand the emergency processes. Likewise, plants in contrast to animals are easy host to handle and viruses that affect them, safer for laboratory work than viruses of humans and animals, another models used in research. Therefore, the interaction plant-virus is a good experimental model for the study of the infectious diseases emergence. The study of virus emergence in plants also has a particular interest, because the viruses can cause economic losses in agricultural crops and threaten the resistance durability of improved plants, it suppose a risk for food security with significant impacts on society, comparable with infectious diseases of humans and domestic animals. To become an emerging pathogen, a virus must jump first from its reservoir host to a new host, then adapt to a new host until the infection within the population becomes independent from the reservoir, and finally must change its epidemiology. In this study, the emergence of pepino mosaic virus (PepMV) in tomato, was selected as experimental model to study the emergence of a virus in a new host specie, as well as the infections of different genotypes of pepper mild mottle virus (PMMoV) in pepper, to study the emergence of a virus that increases its pathogenicity in a previously resistant host. The study of both Pathosystems increased our knowledge about the ecological and evolutionary factors in the two first phases of the emergence of viral diseases in plants. The PepMV is an emerging pathogen in tomato (Solanum lycopersicum L.) in the world, which was first described in 1980 by infecting pepino (Solanum muricatum L.) in Peru, and almost after a decade caused an epidemic in tomato crops in Netherlands. The introduction to Europe was possibly through infected tomato seeds from Peru, and from then have been described new isolates that are grouped in four strains (EU, LP, CH2, US1) that infect tomato. However, the process of its emergence from pepino up tomato is a very interesting question, because it is one of the newest emerging viruses and economically important. For the PepMV emergence in tomato, wild tomato samples from southern Peru were collected, and the presence and diversity of PepMV isolates were analyzed and characterized at biological (host range) and genetics (genomic sequences) levels. Isolates from PMMoV have been described in different world regions which have acquired the ability to infect pepper varieties that were previously resistants (Capsicum spp), it means, a typical case of virus emergence which involves the host range extension and an increased pathogenicity. This is of great interest due to involve the use of resistant varieties obtained by breeding, which is the most effective way to control virus. To study the emergence of highly pathogenic genotypes of PMMoV, biological clones from field isolates whose pathogenicity was known were analyzed (P1,2) and by mutagenesis we increased its pathogenicity (P1,2,3 and P1,2, 3,4), introducing the mutations described as responsible for these phenotypes. We analyzed whether the increased pathogenicity involves a trade-off in fitness of PMMoV genotypes. For this aim, different components of virus fitness in different hosts with several resistance alleles were evaluated. The results of this thesis show: i). The potential of wild plants as reservoirs of emerging viruses, in this case wild tomatoes in southern Peru, and the existence in these plants of PepMV isolates of a new undescribed strain that we call PES. ii) The host range expansion is not a strict condition for the plant virus emergence. iii) The adaptation is the most likely mechanism in the PepMV emergence in cultivated tomato. iv) The increased pathogenicity has a pleiotropic effect on several fitness components, besides the sign and magnitude of this effect depends on the virus genotype, the host and the interaction of both.
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A 1369 bp DNA fragment (Sc) was isolated from a full-length clone of sugarcane bacilliform badnavirus (ScBV) and was shown to have promoter activity in transient expression assays using monocot (banana, maize, millet and sorghum) and dicot plant species (tobacco, sunflower, canola and Nicotiana benthamiana). This promoter was also tested for stable expression in transgenic banana and tobacco plants. These experiments showed that this promoter could drive high-level expression of the beta-glucuronidase (GUS) reporter gene in most plant cells. The expression level was comparable to the maize ubiquitin promoter in standardised transient assays in maize. In transgenic banana plants the expression levels were variable for different transgenic lines but was generally comparable with the activities of both the maize ubiquitin promoter and the enhanced cauliflower mosaic virus (CaMV) 35S promoter. The Sc promoter appears to express in a near-constitutive manner in transgenic banana and tobacco plants. The promoter from sugarcane bacilliform virus represents a useful tool for the high-level expression of foreign genes in both monocot and dicot transgenic plants that could be used similarly to the CaMV 35S or maize polyubiquitin promoter.
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La familia Rhabdoviridae incluye varios patógenos económicamente importantes de cultivos, entre los más de 70 virus que afectan plantas. Estos últimos se clasifican en los géneros Cytorhabdovirus y Nucleorhabdovirus, dependiendo de si producen inclusiones en el espacio perinuclear, o si desarrollan viriones citoplasmáticos. Los integrantes de esta familia infectan gran cantidad de monocotiledóneas y dicotiledóneas y la mayoría son dependientes de transmisión por insectos. Las interacciones virus-vector son altamente específicas, y se ha registrado la replicación en insectos, del rhabdovirus que transmiten a las plantas. Cada especie de rhabdovirus induce un amplio espectro de síntomas en sus plantas huéspedes, y estos van desde la falta de efectos discernibles hasta la muerte total de la planta. El maíz (Zea mays L.) es el cultivo más ampliamente distribuido a nivel mundial y uno de los principales cultivos de cereales, ubicándose tercero en el ranking de producción en el mundo. En maíz se ha citado la presencia de varios rhabdovirus, entre estos American wheat striate mosaic virus (AWSMV), Cereal chlorotic mottle virus (CCMV), Maize mosaic virus (MMV), Maize sterile stunt virus (strains of Barley yellow striate virus), Northern cereal mosaic virus (NCMV) y Maize fine streak virus (MFSV). Ninguno de ellos reportado en Argentina. Desde 2001 un rhabdovirus es observado, por sintomatología y microscopía electrónica, en plantas de maíz de diferentes localidades de la provincia de Córdoba. Esta virosis pudo ser transmitida en dos oportunidades a plantas de maíz sanas mediante Peregrinus maidis y logró amplificarse mediante RT-PCR con iniciadores degenerados, el gen de la polimerasa L. Nuestra hipótesis es que el agente causal de la sintomatología de mosaico estriado amarillo en maíz sería un rhabdovirus emergente en Argentina, diferente de Maize mosaic virus (MMV), transmitido por delfácidos, que puede aislarse y mantenerse en condiciones controladas. El objetivo del presente trabajo es generar conocimientos biológicos, moleculares y epidemiológicos sobre el agente causal de la sintomatología en maíz de mosaico estriado amarillo. Para ello se colectarán plantas de maíz con sintomatología de mosaico estriado amarillo, en distintas localidades donde se presente la sintomatología. Las muestras se observarán al microscopio electrónico en cortes ultrafinos y en “leaf dip". Los viriones se purificarán, extraerá el RNA de los mismos, y obtendrá la secuencia de nucleótidos, para compararla con otras publicadas de virosis vegetales y se obtendrán homologías. Se realizarán transmisiones experimentales de esta virosis, por incisiones vasculares y mediante el empleo de diferentes especies de insectos vectores. Importancia del proyecto El avance de patógenos tropicales hacia zonas templadas es una de las causas de la aparición de las virosis emergentes, que se caracterizan por producir epifítias al ingresar a nuevos ecosistemas. El Maize mosaic virus (MMV) es un rhabdovirus que produce una de las virosis más importantes del maíz en el continente americano. Determinar la identidad del agente etiológico del mosaico estriado amarillo y establecer su relación con MMV es fundamental para desarrollar medidas proactivas y diseñar estrategias de manejo de esta nueva enfermedad.
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The genetic diversity of begomovirus isolates from tomato (Lycopersicon esculentum) fields in the Southeastern region of Brazil was analyzed by direct sequencing of PCR fragments amplified by using universal oligonucleotides for the begomovirus DNA-A, and subsequent computer-aided phylogenetic analysis. Samples of tomato plants and associated weeds showing typical symptoms of virus infection were collected at seven locations in the states of Minas Gerais, Espírito Santo and Rio de Janeiro. A total of 137 out of 369 samples were infected with a begomovirus based on PCR analysis. Phylogenetic analysis indicated a high degree of genetic diversity among begomoviruses infecting tomatoes in the sampled area. One species (Tomato chlorotic mottle virus, TCMV) occurs predominantly in Minas Gerais, whereas in Rio de Janeiro and Espírito Santo a distinct species, not yet fully characterized, predominates. Phylogenetic analysis further indicates the presence of an additional four possible new species. This high degree of genetic diversity suggests a recent transfer of indigenous begomovirus from wild hosts into tomatoes. The close phylogenetic relationship verified between begomovirus infecting tomato and associated weeds favors this hypothesis.
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Nas áreas produtoras de feijão (Phaseolus vulgaris) do Estado do Paraná observa-se anualmente a ocorrência do vírus do mosaico em desenho do feijoeiro (Bean rugose mosaic virus, BRMV), principalmente em infecções mistas com o vírus do mosaico dourado do feijoeiro (Bean golden mosaic virus, BGMV), acarretando maior severidade de sintomas e causando perdas na produção. Recentemente constatou-se a presença do vírus do mosaico severo do caupi (Cowpea severe mosaic virus, CPSMV) associado a sintomas de queima do broto em plantações de soja (Glycine max) na região de Londrina, sendo este um fato novo no Estado. Neste trabalho, parte do RNA2 de dois comovirus isolados de soja no Paraná foram clonados e sequenciados, sendo 600 pares de bases (pb) do BRMV-PR e 594 pb do CPSMV-PR. Posteriormente, as seqüências correspondentes de aminoácidos foram comparadas com seis seqüências de vírus do gênero Comovirus depositadas no GenBank. Com base nestes dados observou-se que o segmento do RNA2 do isolado CPSMV-PR apresentou homologia de 85% com parte de uma seqüência já conhecida do RNA2 do CPSMV, enquanto que o segmento do RNA2 do isolado BRMV-PR apresentou homologia de 39% com o CPSMV, e de 44% com o Bean pod mottle virus (BPMV). Este trabalho apresenta pela primeira vez dados de sequenciamento parcial do BRMV, o que poderá contribuir para sua completa caracterização molecular e para o estabelecimento de estratégias para obtenção de plantas resistentes ao vírus.
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O presente trabalho teve como objetivo a identificação e caracterização de um potyvírus isolado de Zinnia elegans, na Região Noroeste do Estado de São Paulo. O potyvírus foi transmitido por inoculação mecânica e apresentou uma gama restrita de hospedeiras sendo que as espécies mais afetadas pertencem à família Asteraceae. Em SDS-PAGE, a massa molecular da proteína capsidial (CP) foi estimada em 33 kDa e, em "Western-blot", reagiu com anti-soro para o Bidens mosaic virus (BiMV). Um fragmento de aproximadamente 820 pb foi amplificado por RT/PCR, clonado e seqüenciado. O fragmento, que inclui o gene da proteína capsidial, mostrou similaridade de aminoácidos do "core" da CP variando de 55% (Tobacco vein mottling virus, TVMV) a 95% (Sunflower chlorotic mottle virus, SuCMoV) e da CP completa de 55% (TVMV) a 91% (SuCMoV). Na região N-terminal, o potyvírus de Zinnia tem uma deleção de quatro aminoácidos (posições 9 a 12 após o sítio de clivagem entre a proteína NIb e a CP) quando comparada com a seqüência do SuCMoV. A análise filogenética agrupou o potyvírus de Zinnia e o SuCMoV em um mesmo ramo em 100% das réplicas, mostrando uma relação de parentesco muito próxima entre esses dois vírus. Os resultados obtidos no presente trabalho demonstraram que o potyvírus de Zinnia e o SuCMoV são estirpes do mesmo vírus. Sugere-se o nome Sunflower chlorotic mottle virus, isolado Zinnia (SuCMoV-Zi), ao potyvírus encontrado em Z. elegans no Brasil.
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Stunting and stem necrosis were noticed in soybeans (Glycine max) grown in 2000/2001 in West Central Brazil the same condition was also observed in the following year in plantations as far as 2,000 km from the initial area. Based on transmission (mechanical, graft, insect vector), purification and serology, electron microscopy and molecular studies the causal agent was determined to be a whitefly-borne carlavirus which is possibly related to Cowpea mild mottle virus (CpMMV).
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The subtropical Northwestern region of Argentina (provinces of Tucumán, Salta, Jujuy, Santiago del Estero and Catamarca) suffers from a high incidence of the whitefly Bemisia tabaci, and the detection of begomoviruses is also common. The Northwest is the main bean-growing region of the country, and approximately 10% of Argentina's soybean crop is grown in this area. We have used a PCR-based assay to establish the identity and genetic diversity of begomoviruses associated with bean and soybean crops in Northwestern Argentina. Universal begomovirus primers were used to direct the amplification of a fragment encompassing the 5' portion of the capsid protein gene. Amplified fragments were cloned, sequenced and subjected to phylogenetic analysis to determine the sequence identity to known begomoviruses. The data indicated the presence of four distinct begomoviruses, all related to other New World begomoviruses. The prevalent virus, which was present in 94% of bean and soybean samples and also in two weed species, is closely related to Sida mottle virus (SiMoV). A virus with high sequence identity with Bean golden mosaic virus (BGMV) was found in beans. The two remaining viruses displayed less than 89% identity with other known begomoviruses, indicating that they may constitute novel species. One of these putative novel viruses was detected in bean, soybean and tomato samples.
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A diversidade genética de vírus pertencentes ao gênero Begomovirus em tomateiro (Lycopersicon esculentum Mill) foi analisada em regiões produtoras do Centro-Oeste paulista. No período de janeiro de 2003 a fevereiro de 2004, cento e sessenta e seis amostras de tomate foram coletadas e a presença de begomovírus observada em 60% das amostras, por PCR, utilizando-se oligonucleotídeos universais para o gênero Begomovirus. O sequenciamento direto do produto de PCR de 16 dessas amostras indicou a possível presença do Tomato severe rugose virus (ToSRV), Sida mottle virus (SiMoV-[BR]) e da espécie tentativa Tomato yellow vein streak virus (ToYVSV-[BR]). Em duas amostras foi detectada uma possível nova espécie de begomovírus. A presença do ToSRV e do SiMoV ainda não havia sido verificada em tomateiro no estado de São Paulo. Estes resultados indicam a existência de diversidade de espécies de begomovírus infectando o tomateiro nesta região, servindo como um alerta para melhoristas que trabalham na busca de fontes de resistência a esse importante grupo de patógenos.
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A resistência em Capsicum spp a tobamovírus é governada pelos genes L¹ a L4. Baseado na capacidade de alguns isolados suplantarem a resistência destes genes, os tobamovírus podem ser classificados nos patótipos P0, P1, P1-2 e P1-2-3. No Brasil, até o momento as três espécies de tobamovírus conhecidas são: Tobacco mosaic virus (TMV), Tomato mosaic virus (ToMV), pertencentes aos patótipos P0 e Pepper mild mottle virus (PMMoV) pertencente ao patótipo P1-2, respectivamente e podem infectar pimentas e pimentões. Oitenta e seis genótipos de pimentão e pimenta foram avaliados quanto à resistência a tobamovírus, sendo 62 de Capsicum annuum, 18 de C. baccatum e seis de C. chinense. Oito acessos de C. annuum, seis de C. baccatum e os acessos ICA #39, Pimenta de cheiro e PI 152225 de C. chinense apresentaram reação de hipersensibilidade ao ToMV, enquanto que o acesso Ancho de C. annuum foi considerado tolerante, permanecendo assintomático, porém permitindo a recuperação do vírus quando inoculado em Nicotiana glutinosa. Para o PMMoV patótipo P1,2 foram avaliados os acessos de pimentão e pimenta considerados resistentes ao ToMV. Somente o PI 152225 de C. chinense desencadeou reação de hipersensibilidade ao PMMoV, sendo fonte potencial de resistência para programas de melhoramento a este vírus no Brasil.
